c89e5203a5
popping up and crashing when the B-29 model is in use. This isn't the right solution; we should fine the NaN condition. But it's harmless and allows development with the B-29 to continue.
241 lines
6.2 KiB
C++
241 lines
6.2 KiB
C++
#include "Math.hpp"
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#include "Propeller.hpp"
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#include "Engine.hpp"
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#include "PropEngine.hpp"
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namespace yasim {
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PropEngine::PropEngine(Propeller* prop, Engine* eng, float moment)
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{
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// Start off at 500rpm, because the start code doesn't exist yet
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_omega = 52.3f;
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_dir[0] = 1; _dir[1] = 0; _dir[2] = 0;
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_variable = false;
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_gearRatio = 1;
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_prop = prop;
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_eng = eng;
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_moment = moment;
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_fuel = true;
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_contra = false;
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}
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PropEngine::~PropEngine()
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{
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delete _prop;
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delete _eng;
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}
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void PropEngine::setMagnetos(int pos)
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{
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_magnetos = pos;
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}
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void PropEngine::setAdvance(float advance)
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{
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_advance = Math::clamp(advance, 0, 1);
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}
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void PropEngine::setPropPitch(float proppitch)
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{
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// update Propeller property
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_prop->setPropPitch(proppitch);
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}
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void PropEngine::setPropFeather(int state)
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{
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// toggle prop feathering on/off
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_prop->setPropFeather(state);
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}
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void PropEngine::setVariableProp(float min, float max)
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{
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_variable = true;
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_minOmega = min;
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_maxOmega = max;
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}
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bool PropEngine::isRunning()
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{
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return _eng->isRunning();
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}
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bool PropEngine::isCranking()
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{
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return _eng->isCranking();
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}
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float PropEngine::getOmega()
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{
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return _omega;
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}
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void PropEngine::setOmega (float omega)
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{
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_omega = omega;
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}
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void PropEngine::getThrust(float* out)
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{
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int i;
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for(i=0; i<3; i++) out[i] = _thrust[i];
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}
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void PropEngine::getTorque(float* out)
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{
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int i;
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for(i=0; i<3; i++) out[i] = _torque[i];
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}
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void PropEngine::getGyro(float* out)
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{
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int i;
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for(i=0; i<3; i++) out[i] = _gyro[i];
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}
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float PropEngine::getFuelFlow()
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{
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return _fuelFlow;
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}
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void PropEngine::stabilize()
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{
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float speed = -Math::dot3(_wind, _dir);
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_eng->setThrottle(_throttle);
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_eng->setMixture(_mixture);
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_eng->setStarter(false);
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_eng->setMagnetos(3);
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bool running_state = _eng->isRunning();
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_eng->setRunning(true);
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if(_variable) {
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_omega = _minOmega + _advance * (_maxOmega - _minOmega);
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_prop->modPitch(1e6); // Start at maximum pitch and move down
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} else {
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_omega = 52;
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}
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bool goingUp = false;
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float step = 10;
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while(true) {
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float ptau, thrust;
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_prop->calc(_rho, speed, _omega * _gearRatio, &thrust, &ptau);
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_eng->calc(_pressure, _temp, _omega);
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_eng->stabilize();
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// Compute torque as seen by the engine's end of the gearbox.
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// The propeller will be moving more slowly (for gear ratios
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// less than one), so it's torque will be higher than the
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// engine's, so multiply by _gearRatio to get the engine-side
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// value.
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ptau *= _gearRatio;
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float etau = _eng->getTorque();
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float tdiff = etau - ptau;
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Math::mul3(thrust, _dir, _thrust);
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if(Math::abs(tdiff/(_moment * _gearRatio)) < 0.1)
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break;
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if(tdiff > 0) {
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if(!goingUp) step *= 0.5f;
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goingUp = true;
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if(!_variable) _omega += step;
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else _prop->modPitch(1+(step*0.005f));
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} else {
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if(goingUp) step *= 0.5f;
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goingUp = false;
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if(!_variable) _omega -= step;
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else _prop->modPitch(1-(step*0.005f));
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}
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}
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// ...and back off
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_eng->setRunning(running_state);
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}
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void PropEngine::init()
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{
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_omega = 0.01f;
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_eng->setStarter(false);
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_eng->setMagnetos(0);
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}
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void PropEngine::integrate(float dt)
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{
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float speed = -Math::dot3(_wind, _dir);
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float propTorque, engTorque, thrust;
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_eng->setThrottle(_throttle);
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_eng->setStarter(_starter);
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_eng->setMagnetos(_magnetos);
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_eng->setMixture(_mixture);
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_eng->setFuelState(_fuel);
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_prop->calc(_rho, speed, _omega * _gearRatio, &thrust, &propTorque);
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if(_omega == 0.0)
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_omega = 0.001; // hack to get around reports of NaNs somewhere...
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propTorque *= _gearRatio;
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_eng->calc(_pressure, _temp, _omega);
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_eng->integrate(dt);
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engTorque = _eng->getTorque();
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_fuelFlow = _eng->getFuelFlow();
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// Turn the thrust into a vector and save it
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Math::mul3(thrust, _dir, _thrust);
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// We do our "RPM" computations on the engine's side of the
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// world, so modify the moment value accordingly.
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float momt = _moment * _gearRatio;
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// Euler-integrate the RPM. This doesn't need the full-on
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// Runge-Kutta stuff.
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float rotacc = (engTorque-propTorque)/Math::abs(momt);
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_omega += dt * rotacc;
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if (_omega < 0)
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_omega = 0 - _omega; // don't allow negative RPM
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// FIXME: introduce proper windmilling
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// Store the total angular momentum into _gyro, unless the
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// propeller is a counter-rotating pair (which has zero net
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// angular momentum, even though it *does* have an MoI for
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// acceleration purposes).
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Math::mul3(_contra ? 0 : _omega*momt, _dir, _gyro);
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// Accumulate the engine torque, it acts on the body as a whole.
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// (Note: engine torque, not propeller torque. They can be
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// different, but the difference goes to accelerating the
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// rotation. It is the engine torque that is felt at the shaft
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// and works on the body.) (Note 2: contra-rotating propellers do
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// not exert net torque on the aircraft).
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float tau = _moment < 0 ? engTorque : -engTorque;
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Math::mul3(_contra ? 0 : tau, _dir, _torque);
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// Iterate the propeller governor, if we have one. Since engine
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// torque is basically constant with RPM, we want to make the
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// propeller torque at the target RPM equal to the engine by
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// varying the pitch. Assume the the torque goes as the square of
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// the RPM (roughly correct) and compute a "target" torque for the
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// _current_ RPM. Seek to that. This is sort of a continuous
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// Newton-Raphson, basically.
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if(_variable) {
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float targetPropSpd = _minOmega + _advance*(_maxOmega-_minOmega);
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float targetOmega = targetPropSpd / _gearRatio; // -> "engine omega"
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float ratio2 = (_omega*_omega)/(targetOmega*targetOmega);
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float targetTorque = engTorque * ratio2;
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float mod = propTorque < targetTorque ? 1.04f : (1.0f/1.04f);
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// Convert to an acceleration here, so that big propellers
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// don't seek faster than small ones.
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float diff = Math::abs((propTorque - targetTorque) / momt);
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if(diff < 10) mod = 1 + (mod-1)*(0.1f*diff);
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_prop->modPitch(mod);
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}
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}
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}; // namespace yasim
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